"""
The axes_divider module provide helper classes to adjust the positions of
multiple axes at the drawing time.

 Divider: this is the class that is used calculates the axes
    position. It divides the given rectangular area into several sub
    rectangles. You initialize the divider by setting the horizontal
    and vertical list of sizes that the division will be based on. You
    then use the new_locator method, whose return value is a callable
    object that can be used to set the axes_locator of the axes.

"""

import matplotlib.transforms as mtransforms

from matplotlib.axes import SubplotBase

from . import axes_size as Size


class Divider(object):
    """
    This is the class that is used calculates the axes position. It
    divides the given rectangular area into several
    sub-rectangles. You initialize the divider by setting the
    horizontal and vertical lists of sizes
    (:mod:`mpl_toolkits.axes_grid.axes_size`) that the division will
    be based on. You then use the new_locator method to create a
    callable object that can be used to as the axes_locator of the
    axes.
    """


    def __init__(self, fig, pos, horizontal, vertical, aspect=None, anchor="C"):
        """
        :param fig: matplotlib figure
        :param pos: position (tuple of 4 floats) of the rectangle that
                    will be divided.
        :param horizontal: list of sizes
                    (:mod:`~mpl_toolkits.axes_grid.axes_size`)
                    for horizontal division
        :param vertical: list of sizes
                    (:mod:`~mpl_toolkits.axes_grid.axes_size`)
                    for vertical division
        :param aspect: if True, the overall rectangular area is reduced
                    so that the relative part of the horizontal and
                    vertical scales have same scale.
        :param anchor: Determine how the reduced rectangle is placed
                       when aspect is True.
        """

        self._fig = fig
        self._pos = pos
        self._horizontal = horizontal
        self._vertical = vertical
        self._anchor = anchor
        self._aspect = aspect
        self._xrefindex = 0
        self._yrefindex = 0
        self._locator = None

    def get_horizontal_sizes(self, renderer):
        return [s.get_size(renderer) for s in self.get_horizontal()]

    def get_vertical_sizes(self, renderer):
        return [s.get_size(renderer) for s in self.get_vertical()]

    def get_vsize_hsize(self):

        from .axes_size import AddList

        vsize = AddList(self.get_vertical())
        hsize = AddList(self.get_horizontal())

        return vsize, hsize


    @staticmethod
    def _calc_k(l, total_size):

        rs_sum, as_sum = 0., 0.

        for _rs, _as in l:
            rs_sum += _rs
            as_sum += _as

        if rs_sum != 0.:
            k = (total_size - as_sum) / rs_sum
            return k
        else:
            return 0.


    @staticmethod
    def _calc_offsets(l, k):

        offsets = [0.]

        #for s in l:
        for _rs, _as in l:
            #_rs, _as = s.get_size(renderer)
            offsets.append(offsets[-1] + _rs*k + _as)

        return offsets


    def set_position(self, pos):
        """
        set the position of the rectangle.

        :param pos: position (tuple of 4 floats) of the rectangle that
                    will be divided.
        """
        self._pos = pos

    def get_position(self):
        "return the position of the rectangle."
        return self._pos

    def set_anchor(self, anchor):
        """
        :param anchor: anchor position

          =====  ============
          value  description
          =====  ============
          'C'    Center
          'SW'   bottom left
          'S'    bottom
          'SE'   bottom right
          'E'    right
          'NE'   top right
          'N'    top
          'NW'   top left
          'W'    left
          =====  ============

        """
        if anchor in list(mtransforms.Bbox.coefs.keys()) or len(anchor) == 2:
            self._anchor = anchor
        else:
            raise ValueError('argument must be among %s' %
                                ', '.join(list(mtransforms.BBox.coefs.keys())))

    def get_anchor(self):
        "return the anchor"
        return self._anchor

    def set_horizontal(self, h):
        """
        :param horizontal: list of sizes
                    (:mod:`~mpl_toolkits.axes_grid.axes_size`)
                    for horizontal division

        .
        """
        self._horizontal = h


    def get_horizontal(self):
        "return horizontal sizes"
        return self._horizontal

    def set_vertical(self, v):
        """
        :param horizontal: list of sizes
                    (:mod:`~mpl_toolkits.axes_grid.axes_size`)
                    for horizontal division

        .
        """
        self._vertical = v

    def get_vertical(self):
        "return vertical sizes"
        return self._vertical


    def set_aspect(self, aspect=False):
        """
        :param anchor: True or False
        """
        self._aspect = aspect

    def get_aspect(self):
        "return aspect"
        return self._aspect

    def set_locator(self, _locator):
        self._locator = _locator

    def get_locator(self):
        return self._locator

    def get_position_runtime(self, ax, renderer):
        if self._locator is None:
            return self.get_position()
        else:
            return self._locator(ax, renderer).bounds

    def locate(self, nx, ny, nx1=None, ny1=None, axes=None, renderer=None):
        """

        :param nx, nx1: Integers specifying the column-position of the
          cell. When nx1 is None, a single nx-th column is
          specified. Otherwise location of columns spanning between nx
          to nx1 (but excluding nx1-th column) is specified.

        :param ny, ny1: same as nx and nx1, but for row positions.
        """


        figW,figH = self._fig.get_size_inches()
        x, y, w, h = self.get_position_runtime(axes, renderer)

        hsizes = self.get_horizontal_sizes(renderer)
        vsizes = self.get_vertical_sizes(renderer)
        k_h = self._calc_k(hsizes, figW*w)
        k_v = self._calc_k(vsizes, figH*h)

        if self.get_aspect():
            k = min(k_h, k_v)
            ox = self._calc_offsets(hsizes, k)
            oy = self._calc_offsets(vsizes, k)

            ww = (ox[-1] - ox[0])/figW
            hh = (oy[-1] - oy[0])/figH
            pb = mtransforms.Bbox.from_bounds(x, y, w, h)
            pb1 = mtransforms.Bbox.from_bounds(x, y, ww, hh)
            pb1_anchored = pb1.anchored(self.get_anchor(), pb)
            x0, y0 = pb1_anchored.x0, pb1_anchored.y0

        else:
            ox = self._calc_offsets(hsizes, k_h)
            oy = self._calc_offsets(vsizes, k_v)
            x0, y0 = x, y


        if nx1 is None:
            nx1=nx+1
        if ny1 is None:
            ny1=ny+1

        x1, w1 = x0 + ox[nx]/figW, (ox[nx1] - ox[nx])/figW
        y1, h1 = y0 + oy[ny]/figH, (oy[ny1] - oy[ny])/figH

        return mtransforms.Bbox.from_bounds(x1, y1, w1, h1)


    def new_locator(self, nx, ny, nx1=None, ny1=None):
        """
        returns a new locator
        (:class:`mpl_toolkits.axes_grid.axes_divider.AxesLocator`) for
        specified cell.

        :param nx, nx1: Integers specifying the column-position of the
          cell. When nx1 is None, a single nx-th column is
          specified. Otherwise location of columns spanning between nx
          to nx1 (but excluding nx1-th column) is specified.

        :param ny, ny1: same as nx and nx1, but for row positions.
        """
        return AxesLocator(self, nx, ny, nx1, ny1)

    def append_size(self, position, size):

        if position == "left":
            self._horizontal.insert(0, size)
            self._xrefindex += 1
        elif position == "right":
            self._horizontal.append(size)
        elif position == "bottom":
            self._vertical.insert(0, size)
            self._yrefindex += 1
        elif position == "top":
            self._vertical.append(size)
        else:
            raise ValueError("the position must be one of left, right, bottom, or top")


    def add_auto_adjustable_area(self,
                                 use_axes, pad=0.1,
                                 adjust_dirs=["left", "right", "bottom", "top"],
                                 ):
        from .axes_size import Padded, SizeFromFunc, GetExtentHelper
        for d in adjust_dirs:
            helper = GetExtentHelper(use_axes, d)
            size = SizeFromFunc(helper)
            padded_size = Padded(size, pad) # pad in inch
            self.append_size(d, padded_size)


class AxesLocator(object):
    """
    A simple callable object, initialized with AxesDivider class,
    returns the position and size of the given cell.
    """
    def __init__(self, axes_divider, nx, ny, nx1=None, ny1=None):
        """
        :param axes_divider: An instance of AxesDivider class.

        :param nx, nx1: Integers specifying the column-position of the
          cell. When nx1 is None, a single nx-th column is
          specified. Otherwise location of columns spanning between nx
          to nx1 (but excluding nx1-th column) is is specified.

        :param ny, ny1: same as nx and nx1, but for row positions.
        """
        self._axes_divider = axes_divider

        _xrefindex = axes_divider._xrefindex
        _yrefindex = axes_divider._yrefindex

        self._nx, self._ny = nx - _xrefindex, ny - _yrefindex

        if nx1 is None:
            nx1 = nx+1
        if ny1 is None:
            ny1 = ny+1

        self._nx1 = nx1 - _xrefindex
        self._ny1 = ny1 - _yrefindex


    def __call__(self, axes, renderer):

        _xrefindex = self._axes_divider._xrefindex
        _yrefindex = self._axes_divider._yrefindex

        return self._axes_divider.locate(self._nx + _xrefindex,
                                         self._ny + _yrefindex,
                                         self._nx1 + _xrefindex,
                                         self._ny1 + _yrefindex,
                                         axes,
                                         renderer)

    def get_subplotspec(self):
        if hasattr(self._axes_divider, "get_subplotspec"):
            return self._axes_divider.get_subplotspec()
        else:
            return None


from matplotlib.gridspec import SubplotSpec, GridSpec

class SubplotDivider(Divider):
    """
    The Divider class whose rectangle area is specified as a subplot geometry.
    """


    def __init__(self, fig, *args, **kwargs):
        """
        *fig* is a :class:`matplotlib.figure.Figure` instance.

        *args* is the tuple (*numRows*, *numCols*, *plotNum*), where
        the array of subplots in the figure has dimensions *numRows*,
        *numCols*, and where *plotNum* is the number of the subplot
        being created.  *plotNum* starts at 1 in the upper left
        corner and increases to the right.

        If *numRows* <= *numCols* <= *plotNum* < 10, *args* can be the
        decimal integer *numRows* * 100 + *numCols* * 10 + *plotNum*.
        """

        self.figure = fig

        if len(args)==1:
            if isinstance(args[0], SubplotSpec):
                self._subplotspec = args[0]
            else:
                try:
                    s = str(int(args[0]))
                    rows, cols, num = list(map(int, s))
                except ValueError:
                    raise ValueError(
                         'Single argument to subplot must be a 3-digit integer')
                self._subplotspec = GridSpec(rows, cols)[num-1]
                # num - 1 for converting from MATLAB to python indexing
        elif len(args)==3:
            rows, cols, num = args
            rows = int(rows)
            cols = int(cols)
            if isinstance(num, tuple) and len(num) == 2:
                num = [int(n) for n in num]
                self._subplotspec = GridSpec(rows, cols)[num[0]-1:num[1]]
            else:
                self._subplotspec = GridSpec(rows, cols)[int(num)-1]
                # num - 1 for converting from MATLAB to python indexing
        else:
            raise ValueError('Illegal argument(s) to subplot: %s' % (args,))


        # total = rows*cols
        # num -= 1    # convert from matlab to python indexing
        #             # ie num in range(0,total)
        # if num >= total:
        #     raise ValueError( 'Subplot number exceeds total subplots')
        # self._rows = rows
        # self._cols = cols
        # self._num = num

        # self.update_params()


        # sets self.fixbox
        self.update_params()

        pos = self.figbox.bounds

        horizontal = kwargs.pop("horizontal", [])
        vertical = kwargs.pop("vertical", [])
        aspect = kwargs.pop("aspect", None)
        anchor = kwargs.pop("anchor", "C")

        if kwargs:
            raise Exception("")

        Divider.__init__(self, fig, pos, horizontal, vertical,
                         aspect=aspect, anchor=anchor)


    def get_position(self):
        "return the bounds of the subplot box"

        self.update_params() # update self.figbox
        return self.figbox.bounds


    # def update_params(self):
    #     'update the subplot position from fig.subplotpars'

    #     rows = self._rows
    #     cols = self._cols
    #     num = self._num

    #     pars = self.figure.subplotpars
    #     left = pars.left
    #     right = pars.right
    #     bottom = pars.bottom
    #     top = pars.top
    #     wspace = pars.wspace
    #     hspace = pars.hspace
    #     totWidth = right-left
    #     totHeight = top-bottom

    #     figH = totHeight/(rows + hspace*(rows-1))
    #     sepH = hspace*figH

    #     figW = totWidth/(cols + wspace*(cols-1))
    #     sepW = wspace*figW

    #     rowNum, colNum =  divmod(num, cols)

    #     figBottom = top - (rowNum+1)*figH - rowNum*sepH
    #     figLeft = left + colNum*(figW + sepW)

    #     self.figbox = mtransforms.Bbox.from_bounds(figLeft, figBottom,
    #                                                figW, figH)

    def update_params(self):
        'update the subplot position from fig.subplotpars'

        self.figbox = self.get_subplotspec().get_position(self.figure)

    def get_geometry(self):
        'get the subplot geometry, eg 2,2,3'
        rows, cols, num1, num2 = self.get_subplotspec().get_geometry()
        return rows, cols, num1+1 # for compatibility

    # COVERAGE NOTE: Never used internally or from examples
    def change_geometry(self, numrows, numcols, num):
        'change subplot geometry, eg. from 1,1,1 to 2,2,3'
        self._subplotspec = GridSpec(numrows, numcols)[num-1]
        self.update_params()
        self.set_position(self.figbox)

    def get_subplotspec(self):
        'get the SubplotSpec instance'
        return self._subplotspec

    def set_subplotspec(self, subplotspec):
        'set the SubplotSpec instance'
        self._subplotspec = subplotspec



class AxesDivider(Divider):
    """
    Divider based on the pre-existing axes.
    """

    def __init__(self, axes, xref=None, yref=None):
        """
        :param axes: axes
        """
        self._axes = axes
        if xref==None:
            self._xref = Size.AxesX(axes)
        else:
            self._xref = xref
        if yref==None:
            self._yref = Size.AxesY(axes)
        else:
            self._yref = yref

        Divider.__init__(self, fig=axes.get_figure(), pos=None,
                         horizontal=[self._xref], vertical=[self._yref],
                         aspect=None, anchor="C")

    def _get_new_axes(self, **kwargs):
        axes = self._axes

        axes_class = kwargs.pop("axes_class", None)

        if axes_class is None:
            if isinstance(axes, SubplotBase):
                axes_class = axes._axes_class
            else:
                axes_class = type(axes)

        ax = axes_class(axes.get_figure(),
                        axes.get_position(original=True), **kwargs)

        return ax


    def new_horizontal(self, size, pad=None, pack_start=False, **kwargs):
        """
        Add a new axes on the right (or left) side of the main axes.

        :param size: A width of the axes. A :mod:`~mpl_toolkits.axes_grid.axes_size`
          instance or if float or string is given, *from_any*
          function is used to create one, with *ref_size* set to AxesX instance
          of the current axes.
        :param pad: pad between the axes. It takes same argument as *size*.
        :param pack_start: If False, the new axes is appended at the end
          of the list, i.e., it became the right-most axes. If True, it is
          inserted at the start of the list, and becomes the left-most axes.

        All extra keywords arguments are passed to the created axes.
        If *axes_class* is given, the new axes will be created as an
        instance of the given class. Otherwise, the same class of the
        main axes will be used.
        """

        if pad:
            if not isinstance(pad, Size._Base):
                pad = Size.from_any(pad,
                                    fraction_ref=self._xref)
            if pack_start:
                self._horizontal.insert(0, pad)
                self._xrefindex += 1
            else:
                self._horizontal.append(pad)

        if not isinstance(size, Size._Base):
            size = Size.from_any(size,
                                 fraction_ref=self._xref)

        if pack_start:
            self._horizontal.insert(0, size)
            self._xrefindex += 1
            locator = self.new_locator(nx=0, ny=0)
        else:
            self._horizontal.append(size)
            locator = self.new_locator(nx=len(self._horizontal)-1, ny=0)

        ax = self._get_new_axes(**kwargs)
        ax.set_axes_locator(locator)

        return ax

    def new_vertical(self, size, pad=None, pack_start=False, **kwargs):
        """
        Add a new axes on the top (or bottom) side of the main axes.

        :param size: A height of the axes. A :mod:`~mpl_toolkits.axes_grid.axes_size`
          instance or if float or string is given, *from_any*
          function is used to create one, with *ref_size* set to AxesX instance
          of the current axes.
        :param pad: pad between the axes. It takes same argument as *size*.
        :param pack_start: If False, the new axes is appended at the end
          of the list, i.e., it became the top-most axes. If True, it is
          inserted at the start of the list, and becomes the bottom-most axes.

        All extra keywords arguments are passed to the created axes.
        If *axes_class* is given, the new axes will be created as an
        instance of the given class. Otherwise, the same class of the
        main axes will be used.
        """

        if pad:
            if not isinstance(pad, Size._Base):
                pad = Size.from_any(pad,
                                    fraction_ref=self._yref)
            if pack_start:
                self._vertical.insert(0, pad)
                self._yrefindex += 1
            else:
                self._vertical.append(pad)

        if not isinstance(size, Size._Base):
            size = Size.from_any(size,
                                 fraction_ref=self._yref)

        if pack_start:
            self._vertical.insert(0, size)
            self._yrefindex += 1
            locator = self.new_locator(nx=0, ny=0)
        else:
            self._vertical.append(size)
            locator = self.new_locator(nx=0, ny=len(self._vertical)-1)

        ax = self._get_new_axes(**kwargs)
        ax.set_axes_locator(locator)

        return ax


    def append_axes(self, position, size, pad=None, add_to_figure=True,
                    **kwargs):
        """
        create an axes at the given *position* with the same height
        (or width) of the main axes.

         *position*
           ["left"|"right"|"bottom"|"top"]

         *size* and *pad* should be axes_grid.axes_size compatible.
        """

        if position == "left":
            ax = self.new_horizontal(size, pad, pack_start=True, **kwargs)
        elif position == "right":
            ax = self.new_horizontal(size, pad, pack_start=False, **kwargs)
        elif position == "bottom":
            ax = self.new_vertical(size, pad, pack_start=True, **kwargs)
        elif position == "top":
            ax = self.new_vertical(size, pad, pack_start=False, **kwargs)
        else:
            raise ValueError("the position must be one of left, right, bottom, or top")

        if add_to_figure:
            self._fig.add_axes(ax)
        return ax

    def get_aspect(self):
        if self._aspect is None:
            aspect = self._axes.get_aspect()
            if aspect == "auto":
                return False
            else:
                return True
        else:
            return self._aspect

    def get_position(self):
        if self._pos is None:
            bbox = self._axes.get_position(original=True)
            return bbox.bounds
        else:
            return self._pos

    def get_anchor(self):
        if self._anchor is None:
            return self._axes.get_anchor()
        else:
            return self._anchor


    def get_subplotspec(self):
        if hasattr(self._axes, "get_subplotspec"):
            return self._axes.get_subplotspec()
        else:
            return None



class HBoxDivider(SubplotDivider):


    def __init__(self, fig, *args, **kwargs):
        SubplotDivider.__init__(self, fig, *args, **kwargs)


    @staticmethod
    def _determine_karray(equivalent_sizes, appended_sizes,
                          max_equivalent_size,
                          total_appended_size):


        n = len(equivalent_sizes)
        import numpy as np
        A = np.mat(np.zeros((n+1, n+1), dtype="d"))
        B = np.zeros((n+1), dtype="d")
        # AxK = B

        # populated A
        for i, (r, a) in enumerate(equivalent_sizes):
            A[i,i] = r
            A[i,-1] = -1
            B[i] = -a
        A[-1,:-1] = [r for r, a in appended_sizes]
        B[-1] = total_appended_size - sum([a for rs, a in appended_sizes])

        karray_H = (A.I*np.mat(B).T).A1
        karray = karray_H[:-1]
        H = karray_H[-1]

        if H > max_equivalent_size:
            karray = (max_equivalent_size - \
                      np.array([a for r, a in equivalent_sizes])) \
                      / np.array([r for r, a in equivalent_sizes])
        return karray


    @staticmethod
    def _calc_offsets(appended_sizes, karray):
        offsets = [0.]

        #for s in l:
        for (r, a), k in zip(appended_sizes, karray):
            offsets.append(offsets[-1] + r*k + a)

        return offsets


    def new_locator(self, nx, nx1=None):
        """
        returns a new locator
        (:class:`mpl_toolkits.axes_grid.axes_divider.AxesLocator`) for
        specified cell.

        :param nx, nx1: Integers specifying the column-position of the
          cell. When nx1 is None, a single nx-th column is
          specified. Otherwise location of columns spanning between nx
          to nx1 (but excluding nx1-th column) is specified.

        :param ny, ny1: same as nx and nx1, but for row positions.
        """
        return AxesLocator(self, nx, 0, nx1, None)


    def _locate(self, x, y, w, h,
                y_equivalent_sizes, x_appended_sizes,
                figW, figH):
        """

        :param nx, nx1: Integers specifying the column-position of the
          cell. When nx1 is None, a single nx-th column is
          specified. Otherwise location of columns spanning between nx
          to nx1 (but excluding nx1-th column) is specified.

        :param ny, ny1: same as nx and nx1, but for row positions.
        """


        equivalent_sizes = y_equivalent_sizes
        appended_sizes = x_appended_sizes

        max_equivalent_size = figH*h
        total_appended_size = figW*w
        karray = self._determine_karray(equivalent_sizes, appended_sizes,
                                        max_equivalent_size,
                                        total_appended_size)

        ox = self._calc_offsets(appended_sizes, karray)

        ww = (ox[-1] - ox[0])/figW
        ref_h = equivalent_sizes[0]
        hh = (karray[0]*ref_h[0] + ref_h[1])/figH
        pb = mtransforms.Bbox.from_bounds(x, y, w, h)
        pb1 = mtransforms.Bbox.from_bounds(x, y, ww, hh)
        pb1_anchored = pb1.anchored(self.get_anchor(), pb)
        x0, y0 = pb1_anchored.x0, pb1_anchored.y0

        return x0, y0, ox, hh

    def locate(self, nx, ny, nx1=None, ny1=None, axes=None, renderer=None):
        """

        :param nx, nx1: Integers specifying the column-position of the
          cell. When nx1 is None, a single nx-th column is
          specified. Otherwise location of columns spanning between nx
          to nx1 (but excluding nx1-th column) is specified.

        :param ny, ny1: same as nx and nx1, but for row positions.
        """


        figW,figH = self._fig.get_size_inches()
        x, y, w, h = self.get_position_runtime(axes, renderer)

        y_equivalent_sizes = self.get_vertical_sizes(renderer)
        x_appended_sizes = self.get_horizontal_sizes(renderer)
        x0, y0, ox, hh = self._locate(x, y, w, h,
                                      y_equivalent_sizes, x_appended_sizes,
                                      figW, figH)
        if nx1 is None:
            nx1=nx+1

        x1, w1 = x0 + ox[nx]/figW, (ox[nx1] - ox[nx])/figW
        y1, h1 = y0, hh

        return mtransforms.Bbox.from_bounds(x1, y1, w1, h1)



class VBoxDivider(HBoxDivider):
    """
    The Divider class whose rectangle area is specified as a subplot geometry.
    """


    def new_locator(self, ny, ny1=None):
        """
        returns a new locator
        (:class:`mpl_toolkits.axes_grid.axes_divider.AxesLocator`) for
        specified cell.

        :param nx, nx1: Integers specifying the column-position of the
          cell. When nx1 is None, a single nx-th column is
          specified. Otherwise location of columns spanning between nx
          to nx1 (but excluding nx1-th column) is specified.

        :param ny, ny1: same as nx and nx1, but for row positions.
        """
        return AxesLocator(self, 0, ny, None, ny1)


    def locate(self, nx, ny, nx1=None, ny1=None, axes=None, renderer=None):
        """

        :param nx, nx1: Integers specifying the column-position of the
          cell. When nx1 is None, a single nx-th column is
          specified. Otherwise location of columns spanning between nx
          to nx1 (but excluding nx1-th column) is specified.

        :param ny, ny1: same as nx and nx1, but for row positions.
        """


        figW,figH = self._fig.get_size_inches()
        x, y, w, h = self.get_position_runtime(axes, renderer)

        x_equivalent_sizes = self.get_horizontal_sizes(renderer)
        y_appended_sizes = self.get_vertical_sizes(renderer)

        y0, x0, oy, ww = self._locate(y, x, h, w,
                                      x_equivalent_sizes, y_appended_sizes,
                                      figH, figW)
        if ny1 is None:
            ny1=ny+1

        x1, w1 = x0, ww
        y1, h1 = y0 + oy[ny]/figH, (oy[ny1] - oy[ny])/figH

        return mtransforms.Bbox.from_bounds(x1, y1, w1, h1)





class LocatableAxesBase:
    def __init__(self, *kl, **kw):

        self._axes_class.__init__(self, *kl, **kw)

        self._locator = None
        self._locator_renderer = None

    def set_axes_locator(self, locator):
        self._locator = locator

    def get_axes_locator(self):
        return self._locator

    def apply_aspect(self, position=None):

        if self.get_axes_locator() is None:
            self._axes_class.apply_aspect(self, position)
        else:
            pos = self.get_axes_locator()(self, self._locator_renderer)
            self._axes_class.apply_aspect(self, position=pos)


    def draw(self, renderer=None, inframe=False):

        self._locator_renderer = renderer

        self._axes_class.draw(self, renderer, inframe)



_locatableaxes_classes = {}
def locatable_axes_factory(axes_class):

    new_class = _locatableaxes_classes.get(axes_class)
    if new_class is None:
        new_class = type("Locatable%s" % (axes_class.__name__),
                         (LocatableAxesBase, axes_class),
                         {'_axes_class': axes_class})

        _locatableaxes_classes[axes_class] = new_class

    return new_class

#if hasattr(maxes.Axes, "get_axes_locator"):
#    LocatableAxes = maxes.Axes
#else:

def make_axes_locatable(axes):
    if not hasattr(axes, "set_axes_locator"):
        new_class = locatable_axes_factory(type(axes))
        axes.__class__ = new_class

    divider = AxesDivider(axes)
    locator = divider.new_locator(nx=0, ny=0)
    axes.set_axes_locator(locator)

    return divider

def make_axes_area_auto_adjustable(ax,
                                   use_axes=None, pad=0.1,
                                   adjust_dirs=["left", "right", "bottom", "top"]):

    divider = make_axes_locatable(ax)

    if use_axes is None:
        use_axes = ax

    divider.add_auto_adjustable_area(use_axes=use_axes, pad=pad,
                                     adjust_dirs=adjust_dirs)

#from matplotlib.axes import Axes
from .mpl_axes import Axes
LocatableAxes = locatable_axes_factory(Axes)
